Anterior plating system and method

ABSTRACT

Systems and methods for stabilizing the spine are provided. For stabilizing the L 5 -S 1  junction, the system includes a plate ( 7 ) that has a generally triangular shape with an upper node ( 8   a ) and a pair of lower nodes ( 9   a   , 10   a ). The upper node ( 8   a ) has a hole ( 8 ) through the plate ( 7 ) to receive a screw ( 11 ) for passage into the L 5  vertebra. The lower nodes ( 9   a   , 10   a ) each include a hole ( 9,10 ) through the plate ( 7 ) to receive screws ( 12, 13 ) for passage into the S 1  vertebra. The system further includes a plate ( 7 ) having a retaining element ( 32 ) for preventing backout of screws inserted through the plate ( 9 ). Instruments and methods for attaching the plate to the spinal column are also provided.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation-in-part application of International Application No. PCT/IB02/01105 filed on Apr. 5, 2002, which claims priority to French Patent Application No. 01 04728, filed Apr. 6, 2001 and also to pending U.S. patent application Ser. No. 09/993,860 filed on Nov. 6, 2001. The present application is also a continuation-in-part application of pending U.S. patent application Ser. No. 09/993,860 filed on Nov. 6, 2001, which claims priority to French Patent Application No. 01 04728, filed Apr. 6, 2001.

FIELD OF THE INVENTION

The present invention related generally to instruments and methods for spinal stabilization, and more particularly to spinal plating systems and methods.

BACKGROUND OF THE INVENTION

Various types of plating devices and systems have been used to stabilize portions of the spine. For cases in which interbody fusion is desired in the lumbro-sacral region, stabilization using posterior plating has been preferred by many surgeons for good fixation and to avoid damage to the vascular and nervous system components adjacent the anterior surfaces of the L5 vertebra. A posterior plating system for stabilization of the L5-S1 junction is disclosed in U.S. Pat. No. 5,127,912 issued Jul. 7, 1992 to Ray and Ashman.

While posterior fixation systems are often used in fusions, the anterior surgical approach for insertion of fusion devices is preferred from several perspectives. Less blood loss and reduced post-operative pain can be achieved, and there is risk of traumatizing nerves. Additionally, the posterior approach impairs muscles, which are vascularized, and ligaments, which are cut. Effective anterior plating could generally avoid the risks associated with posterior surgery, particularly if an anterior approach is used which is also as minimally invasive as possible, since it is then only necessary to move aside soft tissues which do not affect the stability of the spinal column.

There is however one zone of the spine where an anterior approach entails a particular risk: the zone corresponding to lumbar vertebrae L4-L5 and the first sacral vertebra S1. In this region, the aorta and the vena cava divide to form the right and left iliac veins and arteries. There is therefore a risk of damaging an important blood vessel during implantation of a conventional fixation system. There is also a risk that important blood vessels could be damaged by screw backout, or simply by protrusion of the plate against the blood vessel. Moreover, between the profiles of vertebrae L5 and S1 there is an angle called the “promontory angle” which is very variable from one individual to another. There can also be sliding between L5 and S1 (spondylolisthesis). These conditions further increase the difficulty and risk factors associated with attachment of a stabilization device anteriorly to the L5-S1 region.

There remains a need for anterior plating systems and methods to provide stability for fusion between vertebrae that is adapted to address the challenges presented above.

SUMMARY OF THE INVENTION

Described briefly according to the illustrated embodiments of the invention, a stabilizer for the lumbar/sacral junction is provided. The stabilizer includes a plate having a generally triangular shape with an upper node and a pair of lower nodes. The upper node has an upper hole to receive a screw for passage into an upper vertebra, such as L5. The lower nodes each include a hole to receive a screw for passage into a lower vertebra, such as S1.

There is also provided a plate for a device for stabilization of vertebrae L5 and S1 that has a generally triangular shape, and includes near its upper vertex, a hole through which a screw is passed for fixing the plate to L5, and two holes situated near its lower vertices through which screws are passed for fixing the plate to S1.

There is also provided an anterior spinal plate system that has a plate with a generally triangular shape and includes on its posterior face a protrusion which extends along at least part of the width of the plate that bears against the lower anterior lip of the lower endplate of L5.

There is additionally provided an anterior spinal plate system that has a plate with a triangular shape and includes, on its posterior face near its lower vertices, protrusions which are intended to come to bear against the lower margin of the salient part of S1. The plate can further include on the edge of its posterior face, in the region of its upper vertex, a ridge-shaped protrusion or at least one anchoring point or spike to contact or anchor in L5.

There is further provided an anterior spinal plate system that has a plate with an upper face, a lower face, and at least one hole therethrough extending between the upper and lower faces. A retaining element extends from the upper face of the plate adjacent the at least one hole. The retaining element has a first form wherein a screw is insertable into the at least one hole and is formable to a second form wherein at least a portion of the retaining element extends over the at least one hole, blocking the screw in the hole.

There is further provided an anterior spinal plate system that includes a plate having a triangular shape and an upper face, a lower face, and holes therethrough extending between the upper and lower faces at each vertex. A retaining element is provided to prevent screw backout. In one form, the retaining element can be clipped, screwed or otherwise secured to the anterior face of the plate and is capable of at least partially covering the holes passed through by the screws. The retaining element can be of substantially circular shape, substantially triangular shape, or spoke shaped.

There is also provided a system for osteosynthesis of the spine for joining vertebrae L5 and S1. The system includes a triangular plate having an upper vertex oriented over L5 and two lower vertices oriented over S1. Each vertex has a hole through which a screw may be passed. The system further includes an interbody device inserted into the disc space separating L5 and S1.

There is further provided a plate having a first surface and a support member extending outwardly from the first surface away from the bony portions to which the plate is attached. A retaining element is securable adjacent the first surface of the plate to prevent bone screws from backing out of the plate holes. The retaining element includes an abutment portion engageable with the support member to position the retaining element on the plate.

There is also provided a plate and bone engaging fastener retaining element securable to the plate. The plate includes at least one sidewall tapered from a lower surface of the plate inwardly toward a center of the plate. The retaining element includes at least one sidewall positionable in substantial alignment with the at least one sidewall of the plate. The at least one retaining element sidewall forms a continuation of the tapered plate sidewall to minimize the lateral extent of the plate/retaining element construct.

There are further contemplated instruments for use during surgical procedures that are used to secure an anterior supplemental fixation plate to the spine. One such instrument includes a plate holder that includes a holding portion mounted on a shaft. The holding portion matches the shape of the lower edge of the plate and is provided with means for establishing and maintaining a defined relative position between the holding portion and the plate. The instrument further includes a support member having guiding portions for directing screws into the plate holes.

Also included are methods for stabilizing a spinal segment. One method includes installing a generally triangular-shaped plate having an upper node along the anterior face of L5 and a pair of lower nodes along the anterior face of S1; installing a first screw from the front of the plate through a single hole in the upper node of the plate into L5; and installing screws from the front of the plate through a hole in each of the lower nodes of the plate and into S1. Variations to the above method and other methods are also contemplated.

The above is intended merely as a summary of various inventive aspects presented in the present application, and is in no way intended to be an exhaustive or all-inclusive recitation of such aspects. Additional aspects, forms, features, embodiments and principles of the present invention will be further described below.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagrammatic representation of the region of vertebrae L5-S1 where a plating system according to the invention is implanted.

FIG. 2 is a representation of the region and plating system of FIG. 1 viewed in profile.

FIGS. 3 a-3 d show, respectively, a plan view, a cross section along 3 b—3 b of FIG. 3 a, a cross section along 3 c—3 c of FIG. 3 a, and a cross section along 3 d—3 d of FIG. 3 a, of an example of a plate according to the present invention.

FIG. 4 is a perspective view of another embodiment of a plate according to the present invention.

FIG. 5 is a perspective view of a plate according to the present invention equipped with one embodiment of a retaining element.

FIG. 6 is a side view of the retaining element on the plate of FIG. 5.

FIGS. 7 a and 7 b show, respectively, a plan view and a view in cross section along 7 b—7 b of FIG. 7 a of another embodiment retaining element.

FIGS. 8 a and 8 b are perspective views of a plate according to the invention equipped with a retaining element according to the example in FIG. 7, the retaining element being either in a non-retaining position (FIG. 8 a) or in a retaining position (FIG. 8 b.)

FIG. 9 is a perspective view of a tool which can be used for securing a plate of the present invention to the L5-S1 region.

FIG. 10 shows the tool from FIG. 9 equipped with a pusher which can be used during fitting of the plate.

FIG. 11 shows the tool from FIG. 9 equipped with a rod for drilling holes into the vertebrae which will accommodate the screws for fixing the plate.

FIG. 12 shows a side view of another embodiment of the tool of FIG. 9.

FIG. 13 is a perspective view of another embodiment of a tool which can be used for securing a plate of the present invention to the L5-S1 region.

FIG. 14 a is a perspective view of a plate according to the present invention equipped with another embodiment retaining element

FIG. 14 b is a perspective view looking at the posterior side of the plate and retaining element of FIG. 14 a.

FIGS. 15 a and 15 b show, respectively, a plan view and a cross-section through line 15 b—15 b of FIG. 15 a of the retaining element of FIG. 13.

FIGS. 16 a—16 c show, respectively, a locking element attachment instrument with the locking element of FIGS. 15 a-15 b engaged thereto.

FIG. 17 is a perspective view of another embodiment plate according to the present invention.

FIG. 18 is a perspective view of the posterior side of the plate of FIG. 17.

FIG. 19 is a cross-section taken along line 19—19 of FIG. 18.

FIG. 20 is a perspective view of a portion of the plate of FIG. 17 with a deformation tool applied thereto.

FIG. 21 is a perspective view of another embodiment plate according to the present invention.

FIG. 22 is a perspective view of yet another embodiment plate according to the present invention.

FIG. 23 is a perspective view of still a further embodiment plate according to the present invention.

FIG. 24 is a perspective view of the posterior side of the plate of FIG. 23.

FIG. 25 is a plan view of the plate of FIGS. 14 a-14 b with an alternate embodiment retaining element attached thereto.

FIG. 26 is a cross-section through line 26—26 of FIG. 25.

FIG. 27 is a plan view of the bottom of the alternate embodiment retaining element of FIG. 25.

FIG. 28 is a cross-section through line 28—28 of FIG. 27.

FIG. 29 is a perspective view of another embodiment plate and variable retaining element attachable thereto.

FIG. 29A is a sectional view of the plate and retaining element of FIG. 29 with the retaining element positioned adjacent to the plate.

FIG. 30 is another perspective view of the plate and variable retaining element of FIG. 29.

FIG. 31 is a top plan view of the plate of FIG. 29.

FIG. 32 is a cross-section through line 32—32 of FIG. 31.

FIG. 33 is a top plan view of the variable retaining element of FIG. 29.

FIG. 34 is a bottom plan view of the variable retaining element of FIG. 29.

FIG. 35 is a cross-sectional through line 33—33 of FIG. 32.

FIG. 36 is a top plan view of a fixed retaining element attachable to the plate of FIGS. 29-32.

FIG. 37 is a bottom plan view of the fixed retaining element of FIG. 36.

FIG. 38 is a cross-section through line 38—38 of FIG. 36.

DESCRIPTION OF THE ILLUSTRATED EMBODIMENTS

For the purposes of promoting an understanding of the principles of the invention, reference will now be made to the embodiments illustrated in the drawings and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended. Any such alterations and further modifications in the illustrated devices, and any such further applications of the principles of the invention as illustrated therein are contemplated as would normally occur to one skilled in the art to which the invention relates.

The present includes a plate in the shape of a triangle. In one application, the plate is inserted in the space available between the left iliac vein and the right iliac artery. The plate is adapted in this way minimize or eliminate interference with the anatomy at the site of implantation. The triangular shape gives the plate a large effective surface area while minimizing the risk of its coming into contact with the blood vessels during its fitting and afterwards. The plate is fixed to the vertebrae by three fixation screws near the vertices of the triangle. In one specific application, the upper screw is fixed to vertebra L5, while the lower two screws are fixed to vertebra S1. While the plate described herein is particularly useful for application along the anterior aspect of the spinal column in the L5-S1 region, application along the lateral aspects or antero-lateral aspects of the spinal column and also in other regions of the spine is also contemplated.

Referring now to FIG. 1, there is a diagrammatic representation of the lumbo-sacral region viewed anteriorly. FIG. 1 shows the last lumbar vertebrae L4, L5 and the first sacral vertebrae S1. L4, L5 and S1 are each separated by discs D. The main blood vessels present in this region are also shown, namely the vena cava 1, which divides at L5 into the right iliac vein 2 and the left iliac vein 3, and the aorta 4 which divides at L5 into the right iliac artery 5 and the left iliac artery 6. The space available in the region between the left iliac vein 3 and right iliac artery 5 makes it difficult to secure a conventional plate having appropriate load carrying capabilities to the L5-S1 junction from an anterior approach.

The plate 7 according to the invention has a generally triangular shape in order to adapt to the space available for its implantation. Holes 8, 9, 10 are provided in the plate 7 to permit its fixation by means of screws 11, 12, 13 penetrating into the vertebrae L5 and S1. A first hole 8 is formed near the upper vertex of plate 7 in an upper node 8 a. Upper node 8 a is intended to be placed adjacent vertebra L5 so that screw 11 penetrates into L5 adjacent its lower margin or edge 14, as is illustrated in FIG. 2. The other two holes 9, 10 are formed near the lower vertices of plate 7 in lower nodes 9 a and 10 a, respectively. Lower nodes 9 a and 10 a are intended to be placed adjacent vertebra S1 so that screws 12, 13 penetrate into S1 adjacent its upper margin or edge 15, as can be seen in FIG. 2. The vertices of plate 7 are rounded to minimize trauma to adjacent tissue.

The fixation of the screws 11, 12, 13 on the margins 14, 15 of the vertebrae concerned, in orientations defined by the configurations of the holes 8, 9, 10, overcomes the problems associated with the different angulations between these vertebrae. These differences in angulation are related to the differing profiles of the vertebrae. It is further contemplated that the size of plate 7 can be reduced so that it does not extend substantially beyond the margins 14, 15 and the edges of the plate smooth and rounded to minimize trauma when in contact with adjacent tissue. While it is contemplated that the overall configuration of plate 7 can be standardized and provided in a range of sizes, the external dimensions can also vary depending on the patient anatomy determined according to pre-operative modeling of the L5-S1 region for the particular patient.

In one specific embodiment, screws 11, 12, and 13 are cancellous bone screws. It is further contemplates that screws 11, 12, and 13 can be any type of bone engaging fastener known in the art. The underside of the heads of screws 11, 12, and 13 can be rounded above the smooth shank portions of the screws received in the holes 8, 9, and 10. The rounded screw heads allow the screws to become well seated in a curved seating surface formed in plate 7 around holes 8, 9, and 10, thus permitting some angulation of the screws relative to the plate 7 as the screws are installed and tightened in place.

FIGS. 3 a-3 d show plate 7 in further detail. As illustrated edges 16, 17, 18 of plate 7 are concave to minimize the lateral and caudal extent of plate 7 between nodes 8 a, 9 a and 10 a. Plate 7 can have a shape between edges 16, 17, and 18 that has a slightly concave curvature on its posterior or lower face 23 in order to better adapt to the anatomy of the spinal column and also a slightly convex curvature along anterior or upper face 19 to minimize anterior protrusion. Hole 8 for implantation of screw 11 in L5 is configured to give screw 11 a significant inclination at an angle α relative to the direction perpendicular to anterior face 19 of plate 7. Holes 9, 10 for implantation of the screws 12, 13 in S1 are configured to give screws 12, 13 a substantially perpendicular orientation relative to the anterior face 19 of the plate 7. As discussed above, it is also contemplated that screws 12, 13 can be provided with a head having a spherical lower bearing surface so that screws 12 and 13 can assume any one of multiple angular orientations with anterior face 19. Plate 7 also includes near its lower edge 17 an opening 20 and near its lower nodes 9 a and 10 a indents 21 and 22, respectively. Opening 20 and indents 21, 22 are intended to allow the plate 7 to be gripped by means of a tool adapted for this purpose, it being understood that hole 20 and indents 21 and 22 constitute only one particular example of such means which can cooperate with a gripping tool. Examples of such a tool will be described below.

Posterior face 23 of plate 7 is intended to be directed towards the vertebrae. Posterior face 23 has a protrusion 24 extending along at least part or substantially all of its width. Protrusion 24 has an upper face 25 that is positioned and configured to bear against the lower lip of the anterior margin 14 of the lower endplate of L5, as can be seen in FIG. 2. The oblique orientation of screw 11 tends to press protrusion 24 against L5, which strengthens the hold of plate 7 on L5 and resists any pivoting effect of plate 7 about screw 11 that may result upon lateral flexion of the spine. As is shown, plate 7 also includes protrusions 26, 27 on its posterior face 23 in the area of lower nodes 9 a, 10 a, along the edges of plate 7. Protrusions 26, 27 are placed along S1 and bear against the anterior face of S1 adjacent margin 15, as can be seen in FIG. 2, so as to help hold plate 7 in place. The anchoring of plate 7 on L5 can also be complemented by a ridge-shaped upper lip 28 (FIGS. 3 b and 3 c), or by one or more points 734 (FIG. 23), formed adjacent edges 16, 18 and extending from posterior face 23 of the plate 7 in the region of upper node 8 a in the area of its contact with the anterior face of L5.

Plate 7 also includes a central opening 29 intended to permit insertion and securement of a retaining element for blocking screws 11, 12, 13 inserted through holes 8, 9 and 10, respectively. Plate 7 includes two openings 30, 31 cooperating with the retaining element. The function of the retaining element is to prevent screws 11, 12, 13 from tending to escape from their receiving seat after they have been tightened onto plate 7.

FIG. 5 shows a plate 7 identical to that in FIG. 3, equipped with a first example of a retaining element 32. Retaining element 32 has a circular or substantially circular shape, the diameter of which allows retaining element 32 partially covers holes 8, 9, 10 after screws 11, 12, 13 are inserted. Retaining element 32, also shown in FIG. 6, includes a central opening 33 and two openings 34, 35 situated on either side of central opening 33. Openings 34, 35 correspond in location to openings 30, 31 of plate 7. Retaining element 32 includes a lower face 36 that includes extending therefrom a series of elastic tabs 37 distributed about central opening 33. It is contemplated that at least two or more tabs 37 are provided. The lower end of each tab 37 includes a beveled end 38 and a bearing surface 40.

After fixation of plate 7 to the vertebrae, retaining element 32 can be put into place on plate 7 in the following way. Using a suitable tool that includes two rods penetrating openings 34, 35 of retaining element 32, retaining element 32 is brought into position toward plate 7, and the ends of the rods are introduced into openings 30, 31 of plate 7. Retaining element plate 32 is then pushed against plate 7 so as to introduce elastic tabs 37 into central opening 29 of plate 7. Beveled ends 38 facilitate this introduction and deflect tabs 37 inwardly toward one another during this introduction. Tabs 37 are thus fitted in central opening 29 of plate 7 and prevent retaining element 32 from becoming dislodged from plate 7. A bearing surface 39 (FIGS. 3 b, 3 d) is formed in central opening 29 of plate 7 to cooperate with bearing surface 40 formed on beveled end 38 of each tab 37. Retaining element 32 can thus be installed by clipping it onto plate 7, and can be dislodged therefrom using a suitable tool that can pry tabs 37 from opening 29. It should be understood that other techniques for positioning retaining element 32 on plate 7 are also contemplated, including simply manually placing tabs 37 in opening 29.

Another embodiment of the plate of the present invention is provided in FIG. 4. Plate 107 is generally identical to plate 7 discussed above except as otherwise noted below. Plate 107 includes holes 109, 110 adjacent nodes 109 a, 110 a, respectively, that have an oblong shape so as to give the surgeon more freedom for the location of implantation of screws 12, 13 in S1. Oblong holes 109, 110 further allow plate 107 to adapt to the postoperative changes in the morphology of the patient. However, in the FIG. 4 embodiment hole 108, adjacent node 108 a, receives screw 11 implanted in L5 and can have a shape exactly adapted to that of the head of screw 11 and prohibits any relative displacement between plate 107 and screw 11 at this level to provide good stability for the implanted plate 107.

Plate 107 includes edges 116, 117, and 118 that define a triangular shape. Edges 116, 117 and 118 can have a concave curvature between the adjacent respective nodes 108 a, 109 a, 110 a. Detents 121, 122 are located adjacent holes 109, 110 along edges 116, 118, respectively, to facilitate holding of plate 107 with a plate holding instrument. A hole 120 is provided between holes 109, 110 which can also be employed with a plate holding instrument and/or retaining element insertion instrument, as discussed further below. A central opening 129 is provided for attachment of a retaining element. A protrusion 124 can extend posteriorly from the posterior surface of plate 107 to abut along the inferior margin of the L5 vertebra when plate 107 is secured to the L5-S1 junction.

Another embodiment retaining element is shown in FIGS. 7 a and 7 b. Retaining element 132 is not circular here but has on its periphery three cutouts 142, 143, 144 that form flange like projections 142 a, 143 a and 144 a. Like retaining element 32, retaining element 132 includes a lower face 136, a central opening 133, and elastic tabs 137 about central opening 133 with beveled ends 138 and bearing surfaces 140. To facilitate rotation with a tool, three openings 145, 146, 147 are formed on retaining element 132, offset 120° relative to one another about central opening 133. A U-shaped opening 148 is also formed in order to define an elastic tongue 149 that lifts when a force is exerted on its posterior face 150. The end of the tongue 149 has a stud 151 on its posterior face.

Retaining element 132 is used as follows. Referring to FIGS. 8 a and 8 b, retaining element 132 can be placed on plate 107 before screw insertion. Retaining element 132 is initially placed on plate 107 so that cutouts 142, 143, 144 leave holes 108, 109, 110 of plate 107 entirely exposed, as shown in FIG. 8 a, permitting insertion and tightening of screws 11, 12, 13 upon positioning of plate 107 on the vertebrae. The positions and dimensions of cutouts 142, 143, 144 are chosen accordingly. With retaining element 132 in this position, stud 151 of tongue 150 is engaged in a receiving seat 130 (FIG. 4) formed on anterior face 119 of plate 107. Plate 107 is then put into place and screws 11, 12, 13 are tightened. A suitable tool is then inserted in one or more of openings 145, 146, 147 of retaining element 132, and retaining element 132 is turned 180° with the aid of this tool. Under the effect of the force applied to it, stud 151 is released from its seat and permits rotation of retaining element 132. Consequently, flanged portions 142 a, 143 a, 144 a of retaining element 132 partially cover holes 108, 109, 110 as shown in FIG. 8 b. Retaining element 132 thus prevents screws 11, 12, 13 from backing out beyond anterior face 119. Retaining element 132 is held in this position by virtue of the engagement of stud 151 in a receiving seat 131 (FIG. 4.) The pre-fitting of retaining element 132 on plate 107 prior to positioning plate 107 on the vertebrae of the patient eliminates the fiddle factor for the surgeon.

Plate 107 of the osteosynthesis device in FIG. 8 has oblong holes 109, 110, but it is understood that retaining element 132 can also be used on plate 7 which has circular holes 9, 10. Those skilled in the art will readily appreciate that the clippable retaining elements 32, 132 described above can have different configurations than those shown herein and still block screws seated in the plate holes.

The present invention also includes an instrument designed for positioning the plates and screws of the present invention as shown in FIGS. 9-11. Instrument 50 will be described with respect to plate 7, it being understood that instrument 50 has application with the other plate embodiments described herein.

Instrument 50 includes a plate holding portion 52 which matches the shape of lower edge 17 of plate 7. Holding portion 52 includes studs (not shown) that are inserted into indents 21, 22. It is further contemplate that holding portion 52 and plate 7 can be provided with any other means of establishing a defined relative position therebetween. Instrument 50 further includes a shaft 53 which is bent and has a grip 54 at its proximal end to allow the surgeon to manipulate instrument 50 and plate 7. Shaft 53 has adjacent its distal end a distal portion 55 perpendicular to anterior surface 19 that supports holding portion 52.

It is contemplated that at least distal portion 53 is hollow, and instrument 50 further includes a rod 56 extending through the hollow distal portion 55 of shaft 53. Rod 56 can be provided with threads and held on shaft 53 by a corresponding thread on an inner wall surface of shaft 53. The distal end of rod 56 lodges in opening 20 of plate 7. The inner wall surface of opening 20 can include a thread corresponding to a thread on the lower end of rod 56. The proximal end of rod 56 opens to the outside of shaft 53 and has a recess 57 for insertion of a screwdriver. Tightening and loosening rod 56 makes it possible for plate 7 and holding portion 52 to be connected and disconnected.

Instrument 50 also includes a tube 58 which can pass through shaft 53 and is connected to it. Tube 58 has an inner passage that allows a rod 59 to be inserted therein and held in position in its internal space. Rod 59 includes at its lower end a point 60 which bears on or embeds in vertebra S1 upon positioning of plate 7 thereon. Instrument 50 further includes a support 61 attached to shaft 53 and arranged substantially horizontally. Support 61 includes a lateral arm 61 a extending to a guide member 61 b that includes three guiding portions 62, 63, 64. First guiding portion 62 is formed on the side of guide member 61 b adjacent shaft 53 and second and third guiding portions 63 and 64 are formed on the side of guide member 61 opposite shaft 53.

Use of instrument 50 to secure plate 7 will now be described. In a first step, plate 7 is fixed on holding portion 52 as described above. The surgeon then positions plate 7 on L5 and S1 at the desired site. Plate 7 can be held at the desired site by penetrating point 60 of rod 59 into S1. Pusher 65, as shown in FIG. 10, is also used to firmly seat plate 7 on L5 and S1. Pusher 65 is a shaft which has at its proximal end a grip 66 and at its distal end a bulb 67 which can lodge in hole 8 of plate 7. Bulb 67 could also lodge in a depression or a hole provided in plate 7 specially adapted for this purpose. Bulb 67 can be replaced by any other means capable of ensuring its function of maintaining the position of pusher 65 bearing on plate 7.

In a second step, pusher 65 is withdrawn and the holes intended to receive screws 11, 12, 13 are drilled in L5 and S1. This drilling is carried out, as is shown in FIG. 11, using a drill rod 68. Drill rod 68 includes at a proximal end a grip 69 and at a distal end a bit 70 capable of drilling a hole in a vertebra to receive a screw. To drill a hole in L5, as is shown in FIG. 11, drill rod 68 is guided through hole 8 of plate 7, and applied against guiding portion 62 of support 61. The position of support 61 and the shape of guiding portion 62 are determined in such a way that the angle of penetration of the drill tip in L5 corresponds to the desired angle of penetration of screw 11. Once the hole in L5 is completed, the holes in S1 for receiving screws 12, 13 are then drilled in a similar manner. The drill rod, however, is oriented away from grip 54 in order to provide the appropriate caudal orientation of screws 12 and 13. Drill rod 68 is then guided through hole 9 and guiding portion 63 of support 61, and through hole 10 and guiding portion 64 of support 61 to drill holes in S1.

Finally, screws 11, 12, 13 are inserted in the holes which have just been drilled and are tightened by means of a conventional screwdriver, which can also be applied against support 61 in a manner similar to what was done for drill rod 68. Plate 7 is then disconnected from holding portion 52 by loosening rod 56. The procedure is completed by putting into place a retaining element to block screws 11, 12, 13, if such a retaining element were provided.

It is contemplated that holding portion 52 can be detachable from shaft 53 to allow the use different sizes of plate holding portions 52. Various holding portions 52 can be provided that are based on various external dimensions of different sized plates 7. Likewise, for the optimum choice of the points of penetration and the values of the angles of penetration of screws 11, 12, 13, the position and orientation of support 61 and its guiding portions can be determined and adjusted by the surgeon before and during the procedure.

Another embodiment of instrument 50 is shown in FIG. 12 and designated as 50′. The elements of instrument 50′ common to instrument 50 are designated therein by the same reference numbers. In this embodiment, tube 58 and rod 59 are replaced by a flexible rod 71 arranged along shaft 53 and passing through its proximal end via a hole 72. At the distal end of flexible rod 71 there is a rigid rod 73 which ends in a bearing surface 74 that will rest on S1 upon positioning of plate 7 at a suitable angle therewith. Flexing of rod 71 provides an indication to the surgeon when such contact between bearing surface 74 and S1 is made.

It will be understood that variants in the details of the design of instrument 50 described herein are contemplated. For example, the means for connecting and disconnecting plate 7 and holding portion 52 can be different than those described. It is possible to use, for example, an instrument in which the distal end of rectilinear portion 55 of shaft 53 can be clipped/unclipped to cooperate with hole 20 of plate 7. For example, as shown in FIG. 13, instrument 50″, except as otherwise noted, is the same as instrument 50 and like elements are designated with the same reference numerals. Instrument 50″ includes a plate holding portion 52″ that includes a foot 72 having a hole 73 therethrough. A fastener 75 extends through hole 73 and engages foot 72 to opening 29 of plate 7. Foot 72 can include a stud (not shown) extending downwardly therefrom that is positionable in hole 20 to prevent rotation of plate 7 about fastener 75. With instrument 50″ plate 7 need not include indents 21, 22, although provision of the same is not precluded.

Referring now to FIGS. 14 a-14 b, another embodiment plate 207 is shown. Plate 207 is identical to plates 7, 107 except with respect to its retaining element 232, and that plate 207 does not include indents for coupling to a plate holder, although the provision of such indents is not precluded. Plate 207 includes upper hole 208 extending through upper node 208 a, first lower hole 209 extending through first lower node 209 a, and second lower hole 210 extending through second lower node 210 a. Plate 207 includes edges 216, 217, 218 extending between anterior face 212 and posterior face 214. A protrusion 233 extends along posterior face 214 below hole 208. A retaining element 232, shown in further detail in FIGS. 15 a-15 b, is secured to anterior face 212 of plate 207 and partially overlaps holes 208, 209, 210 when screws 11, 12 and 13 are positioned therein.

Retaining element 232 is secured to plate 207 by a locking fastener 230 that threadingly engages a central opening 229 of plate 207. Retaining element 232 has a generally triangular shape with rounded apices that generally match the outer edge profile of plate 207. Retaining element 232 can include a hole 235 that can be used to assist in placing retaining element 232 to its proper positioning on anterior face 212 or to hold retaining element 232 in position as locking fastener 230 is threaded into opening 229. Locking fastener 230 engages a central hole 238 of retaining element 232 and contacts lip 239 extending therearound to hold it against anterior face 212. As shown in FIG. 14 b, locking fastener 230 also extends through opening 229 to posterior face 214. Opening 229 has inwardly biased tangs 236 extending therearound at its lower opening, which can be recessed with respect to posterior face 214. Tangs 236 clamp onto locking fastener 230 and prevent it from unthreading.

It is contemplated that retaining element 232 can be provisionally fastened to plate 207 with locking fastener 230 threaded partially into opening 229 before placement of plate 207 on the vertebrae. In this manner, retaining element 232 is rotatable with respect to anterior face 212, and can oriented such that holes 208, 209, and 210 are not blocked thereby. After screws 11, 12 and 13 are inserted to secure plate 207 to the vertebrae, retaining element 232 can be oriented to its FIG. 14 a position and locking fastener 230 advanced in opening 229 to engage tangs 236.

However, with plate 207 applied anteriorly to the L5/S1 region, it is desirable that the lateral extent of plate 207 and retaining element 232 be minimized to avoid contact with the delicate tissues and vasculature adjacent the L5/S1 region. In FIGS. 16 a-16 c there in shown retaining element 232 captured on the distal end of a retaining element attachment instrument 800. Attachment instrument 800 prevents retaining element 232 from rotating relative to plate 207 as it is attached thereto.

Attachment instrument 800 includes a proximal handle 802, an outer shaft 804 extending distally from handle 802, and an inner member 806 rotatably received in outer shaft 804. In one embodiment, inner member 806 is threadingly engaged in outer shaft 804. Inner member 806 includes a distal end 808 extending from outer shaft 804 configured to engage the tool recess in the head of locking fastener 230. It is contemplated that the head of locking fastener 230 can be provisionally captured on distal end 808 to assist in inserting retaining element 230 into the patient. Inner member 806 includes a proximal end 810 having a rectangular head or the like for engaging a tool for application of a rotary force to inner member 806 while outer shaft 804 is held stationary with handle 802.

Outer shaft 804 includes a distal foot 812 extending laterally from outer shaft 804 and an extension 814 extending distally from foot 812. Extension 814 can be in the form of a rod or shaft sized to engage a receptacle in retaining element 232, such as hole 235 through retaining element 232, as shown in FIGS. 16 a and 16 b. With retaining element 232 captured on locking fastener 230, and inner member 806 engaging locking fastener 230, extension 814 extends through hole 235 of retaining element 232.

In one specific application, plate 207 is positioned on the L5 and S1 vertebrae and secured thereto with bone screws using instrument 50″ as discussed above. With instrument 50″ positioning plate 207 and guiding bone screw placement, retaining element 230 cannot be secured to plate 207 until instrument 50″ is removed. With the plate secured to the L5 and S1 vertebrae, instrument 50″ is removed from plate 207 for attachment of retaining element 232 with attachment instrument 800.

Retaining element 232 and locking fastener 230 are positioned on the distal end of attachment instrument 800 as shown in FIGS. 16 a and 16 b. Retaining element 232 is oriented with respect to plate 207 so that each of the corners of retaining element 232 is positioned over respective ones of the plate holes. In this orientation retaining element 232 is inserted in the patient to plate 207. The distal end of extension 814 is inserted at least partially into a receptacle in plate 207, such as hole 220, and the distal end of locking fastener 230 is positioned at the anterior surface entrance of opening 229 of plate 207. Extension 814 and locking fastener 230 maintain the desired orientation of retaining element 232 and prevent retaining element 232 from rotating relative to plate 207 as retaining element 232 is secured thereto with locking fastener 230. As inner member 806 is rotated relative to outer shaft 804 to thread locking fastener 230 into opening 229, inner member 806 distally advances relative to outer shaft 804. As locking fastener 230 is threaded into opening 229, retaining element 232 advances along extension 814 until retaining element 232 is secured against the upper surface of plate 207 with locking fastener 230.

Referring now to FIGS. 17-20, another embodiment plate 407 is shown. Plate 407 is identical to plates 7, 107 except with respect to the configuration of the retaining elements and their attachment to plate 407, and also in that plate 407 does not include indents for coupling to a plate holder, although the provision of such indents is not precluded. Plate 407 includes edges 416, 417, 418 extending between an anterior face 412 and a posterior face 414. Plate 407 can further include upper protrusion 432 along posterior face 414 for contacting the lower margin of L5. Plate 407 further includes a central hole 436 and a lower instrument engaging hole 438 that can be used to engage an insertion instrument.

Plate 407 includes an upper node 420 a, a first lower node 420 b and a second lower node 420 c each having a screw hole 422 a, 422 b, 422 c, respectively, formed therethrough. Upper retaining element 424 a is connected with anterior face 412 of plate 407 by a connecting element 426 a that is formed as an integral unit with plate 407 and upper retaining element 424 a. A gap 430 a is formed between upper retaining element 424 a and anterior face 412. Upper retaining element 424 a extends at least partially around upper hole 422 a and, in its FIG. 17 position, allows entry of a screw 11 through upper hole 422 a for attachment to L5. After screw 11 is seated in upper hole 422 a, upper retaining element 424 a can be bent or deformed from its first form of FIG. 17 to a second form shown in FIG. 20. In its second form upper retaining element 424 a extends over upper hole 422 a and blocks screw 11 if it were to unseat from upper hole 422 a and backout from plate 407.

There is further provided first and second lower retaining elements 424 b, 424 c associated with first lower node 420 b and second lower node 420 c, respectively. First and second lower retaining elements 424 b, 424 c are connected with anterior face 412 of plate 407 by connecting elements 426 b, 426 c, respectively, that are formed as an integral unit with plate 407 and first and second lower retaining elements 424 b, 424 c. Gaps 430 b, 430 c are formed between each first and second lower retaining element 424 b, 424 c, respectively, and anterior face 412. Each of the first and second lower retaining elements 424 b, 424 c extends at least partially around a corresponding one of the first and second lower holes 422 b, 422 c. In their FIG. 17 position, first and second lower retaining elements 424 b, 424 c allow entry of screws 12, 13 through first and second lower holes 422 b, 422 c for attachment to S1. After screws 12, 13 are seated in first and second lower holes 422 b, 422 c, first and second lower retaining elements 424 b, 424 c are deformed or bent by, for example, applying a bending force, from their first form of FIG. 17 to a second form shown in FIG. 20. In their second form, first and second lower retaining elements 424 b, 424 c each extend over respective ones of first and second lower holes 422 b, 422 c and block a corresponding one of the screws 12, 13 if one were to unseat from its hole and backout from plate 407.

Plate 407 also provides an alternate arrangement for posterior protrusion 432 intended to contact L5. As shown in FIG. 19, protrusion 432 is intercepted by hole 422 a and is thus not continuous along the width of plate 407. In contrast, protrusion 24 of plate 7 is situated below hole 8 and is continuous along the width of plate 7. It should be understood, however, that the location of the L5 posterior protrusion for the plates described herein can be varied based on patient anatomy and either of the above locations for the L5 posterior protrusion can be provided with any of the plate embodiments described herein.

As also shown in FIG. 20, there is providing a forming tool 450 that is operable to simultaneously apply a bending force to retaining elements 424 a, 424 b, 424 c to move these retaining elements from their first form to their second form overlapping the adjacent plate hole. Tool 450 has an outer shaft 452 coupled to a distal working end 454. Distal working end 454 includes a first forming member 456 a positionable adjacent upper retaining element 424 a, a second forming member 456 b positionable adjacent first lower retaining element 424 b, and a third forming member (not shown) positionable adjacent second lower retaining element 424 c when tool 450 is mounted on central hole 436 of plate 407. The forming members 456 a, 456 b are wedge shaped and are pivotally coupled to working end 454 at upper ends 458 a, 458 b and their opposite thicker lower ends 460 a, 460 b are normally biased towards the center of shaft 452. An inner actuator 462 housed in outer shaft 452 and working end 454 is movable with respect thereto in the direction of arrow P. Actuator 463 slides distally along the wedge-shaped forming members and pivots their lower ends about their respective upper ends and away from the center of tool 450 into contact with the adjacent retaining element.

Tool 450 is representative of one type of instrument that can be used to bend or adjust the formable retaining elements from their first form to their second form. Other instruments and techniques are also contemplated. For example, the retaining elements can be individually bent or adjusted by a tool inserted into the gap along the retaining element and manipulated therein to apply a bending force. The retaining elements can also be made from a shape memory alloy and temperature applied thereto in order to form the retaining element from their first form to their second form

Referring now to FIG. 21, another embodiment plate 507 is shown. Plate 507 is identical to plate 407 except with respect to the configuration of the retaining elements and their attachment to plate 507. Plate 507 includes an upper node 520 a, a first lower node 520 b and a second lower node 520 c each having a screw hole formed therethrough. A base member 526 is connected to or formed as an integral unit with plate 507 and extends from its anterior face 512. Base member 526 has an upper retaining element 524 a adjacent upper hole 522 a, a first lower retaining element 524 b adjacent first lower hole 522 b, and a second lower retaining element 524 c adjacent second lower hole 522 c. Gaps 530 a, 530 b, and 530 c are formed between base member 526 and respective ones of the retaining elements 524 a, 524 b and 524 c. Retaining elements 524 a, 524 b and 524 c arc illustrated in FIG. 21 in their first form allowing screw insertion into the adjacent holes. As discussed above with respect to retaining elements of plate 407, retaining elements 524 a, 524 b and 524 c can be bent or otherwise moved into a second form after screw insertion wherein the retaining elements extend over the holes of plate 507 and prevent screw backout.

Referring now to FIG. 22, another embodiment plate 607 is shown. Plate 607 is identical to plate 407 except with respect to the configuration of the retaining elements and their attachment to plate 607. Plate 607 includes an upper node 620 a, a first lower node 620 b and a second lower node 620 c each having a screw hole formed therethrough. Plate 607 includes a wall 626 around its perimeter and around holes 622 a, 622 b, 622 c. Wall 626 forms a central opening 627 in the middle of plate 607, and wall 626 separates central opening 627 and holes 622 a, 622 b, and 622 c. Central opening 627 enables visualization of an implant I in the disc space and accommodates insertion of a forming tool, such as tool 450 discussed above, alongside upper retaining element 624 a adjacent upper hole 622 a, first lower retaining element 624 b adjacent first lower hole 622 b, and second lower retaining element 624 c adjacent second lower hole 622 c. Gaps 630 a, 630 b, and 630 c are formed between each retaining element 624 a, 624 b, 624 c and wall 626, respectively. Retaining elements 624 a, 624 b and 624 c are illustrated in FIG. 22 in their first form allowing screw insertion into the adjacent holes. As discussed above with respect to retaining elements of plate 407, retaining elements 624 a, 624 b and 624 c can be bent or moved to a second form after screw insertion wherein the retaining elements extend over the holes of plate 607 and prevent screw backout. Further, cutouts 633 a, 633 b, and 633 c are provided in the recess of the hole adjacent retaining elements 624 a, 624 b, and 624 c, respectively, to receive a forming tool inserted therein, which tool can then be pivoted to bend the adjacent retaining element.

Referring now to FIGS. 23-24, another embodiment plate 707 is shown that is generally the same as the other plate embodiments discussed herein except as otherwise noted below. Plate 707 includes an upper node 720 a and first and second lower nodes 720 b, 720 c. Upper node 720 a and lower nodes 720 b, 720 c each has a hole for receiving a bone screw 11, 12, 13, respectively. Plate 707 further includes an anterior face 712 and an opposite posterior face 714. The edges of plate 707 are not concave between the nodes, but could be provided as such. In this embodiment, plate 707 is provided with a pair of spikes 734 extending from posterior face 714 at the upper end of plate 707. Spikes 714 are embeddable in the upper vertebral body to which the plate is to be secured, such as L5. Such spikes could likewise be provided with any of the plate embodiments described herein.

Plate 707 further includes a retaining element 726 rotatably attached to central hole 736 in the middle of plate 707 by a pin 730. Retaining element 726 has an upper apex 724 a, first lower apex 724 b and second lower apex 724 c. Retaining element 726 has a first position (not shown) wherein retaining element 726 is positioned with respect to plate 707 so that apices 724 a, 724 b, 724 c are not positioned over the screw holes through the plate nodes 720 a, 720 b, 720 c. After screw insertion, retaining element 726 is rotated with respect to plate 707 to position apices 724 a, 724 b, 724 c over the screw holes through nodes 720 a, 720 b, 720 c to prevent screw backout. A spring blade 728 is initially positioned substantially within a slot 732 formed in retaining element 726. Spring blade 728 can be moved out of slot 732 and into contact with anterior face 712 to prevent further rotation of retaining element 726. The orientation between spring blade 728 and anterior face 712 can be such that anterior face 712 biases spring blade 728 upward to provide frictional engagement therebetween causing spring blade 728 to remain in its extended position shown in FIG. 23.

Further embodiments of retaining elements for blocking screws 11, 12, 13 are also contemplated. For example, the anterior face of the plate could be provided with a seat open on one side and bordered by rails or grooves that allow the retaining element to be slidably inserted therein after the screws have inserted. The retaining element could be held in the receiving scat by means of an elastic tongue having formed on its lower face a stud which, upon complete insertion of the retaining element, will penetrate into a receiving seat formed on the anterior surface of the plate.

Referring now to FIGS. 25-28, another embodiment retaining element 900 will be described. Retaining element 900 has a generally triangular shape and is sized to fit on a triangular plate, such as plate 207. Retaining element 900 includes an upper node 902, a first lower node 904 and a second lower node 906. Retaining element 900 includes a central hole 908 sized to receive a locking fastener, such as locking fastener 230, to secure retaining element 900 in opening 229 of plate 207. Hole 908 includes a recess 908 a that allows the head of locking fastener 230 to be recessed therein. Retaining element 900 also includes an alignment hole 910 alignable with hole 220 of plate 207. Alignment hole 910 is sized to receive an extension of an attachment instrument such as discussed above with respect to attachment instrument 800 and retaining element 232.

Each of the nodes 902, 904, 906 has a profile as shown in FIG. 25 so that each node 902, 904, 906 extends over the screw holes of plate 207 and the heads of the screws positioned therein. In the illustrated embodiment, each node 902, 904, 906 has a semi-circular shape; however, other shapes are also contemplated. As shown in FIGS. 27 and 28, each node 902, 904, 906 includes an engagement member 912, 914, 916, respectively, extending therefrom into the adjacent screw hole. Engagement member 912 included a central protrusion 912 a positionable in the tool engaging recess 11 a of bone screw 11, as shown in FIG. 26. A recess 912 b extends around central protrusion member 912 a, and recess 912 b is sized to receive the upper surface of the head of bone screw 11. Central protrusion 912 a is sized to engage bone screw 11 in tool engaging recess 11 a so that the sides of tool engaging recess 11 a contact central protrusion 912 a, fixing bone screw 11 relative to plate 207.

Engagement members 914, 916 similarly include a central protrusion 914 a, 916 a and recess 914 b, 916 b therearound to fix the bone screws in the lower holes of plate 207. A bone screw guide, such as shown with instrument 50″, can be used to engage the bone screws through the plate holes so that the heads of the bone screws are properly positioned relative to plate 207 for engagement with engagement members 912, 914, 916. With the heads of the bone screws engaged by retaining element 900, the bone screws are fixed relative to plate 207.

Engagement members 912, 914 and 916 are received in the adjacent plate holes so that retaining element 900 can lie flush against the upper surface of plate 207, preventing tissue migration between retaining element 900 and the upper surface of plate 207. As shown in FIG. 26, retaining element 900 extends above the upper surface of plate 207 and includes a thickness that provides sufficient stiffness to retaining element 900 to resisting bending forces and ensure positive fixation of the bone screws should they back out from the vertebra in which they are engaged.

It is contemplated that plates described herein can be provided in a kit with one or more retaining elements and instruments for inserting the plate and retaining element. For example, plate 207 can be provided with the requisite bone screws and insertion instrument, such as instrument 50″. A pair of retaining elements can be provided to give the surgeon flexibility in selecting the desired means for securing plate 207 to the L5/S1 vertebrae. For example, retaining element 232 and locking fastener 230, when secured to plate 207, allow the bone screws to pivot and compressive force to be maintained on the graft, implant or other device between the L5 and S1 vertebrae. Retaining element 900 and locking fastener 230, when secured to plate 207, fix the bone screws relative to plate 207 maintaining the spacing between the L5 and S1 vertebrae.

Referring now to FIGS. 29-30, another embodiment plating system 1000 is shown that includes a plate 1007. Plate 1007, except as otherwise discussed, can be generally the same as plate 207 discussed above. Plate 1007, as further shown in FIGS. 31-32, includes upper hole 1008 extending through upper node 1008 a, first lower hole 1009 extending through first lower node 1009 a, and second lower hole 1010 extending through second lower node 1010 a. Plate 1007 includes edges 1016, 1017, 1018 extending between anterior face 1012 and posterior face 1014. Edges 1016, 1017, 1018 can be concavely curved between respective ones of the adjacent nodes 1008 a, 1009 a, 1010 a. A protrusion 1024 extend from posterior face 1014 to contact the inferior margin of the L5 vertebra.

A retaining element 1032, shown in further detail in FIGS. 33-35, is secured to a first surface such as anterior face 1012 of plate 1007 and partially overlaps holes 1008, 1009, 1010 when bone engaging fasteners, such as bone screws 11, 12 and 13, are positioned therein. Retaining element 1032 can be secured to plate 1007 by a locking fastener 1030 that engages a central opening 1029 of plate 1007 by threaded engagement, clips, or other fastening arrangement. Retaining element 1032 has a generally triangular shape with rounded apices that generally match the outer edge profile of plate 1007, although other shapes for plate 1007 and retaining element 1032 are also contemplated. Retaining element 1032 can include a hole 1035 alignable with hole 1020 of plate 1007. Holes 1035 and 1020 can be used to assist in placing locking element 1032 to its proper positioning on anterior face 1012 and to non-rotatably hold retaining element 1032 in position as locking fastener 1030 is engaged in central opening 1029, such as discussed above with respect to plate 207, retaining element 232 and the instruments of FIGS. 16 a-16 c. In the illustrated embodiment, locking fastener 1030 can extend through central opening 1029 to posterior face 1014 where it engages inwardly biased tangs 1036 located adjacent posterior face 1014.

In FIG. 29A, there is shown a sectional view of plate 1007 and retaining element 1032 having a configuration in which the lateral profile of plating system 1000 is minimized. Edges 1016 and 1018 of plate 1007 each include a profile that tapers from bottom or posterior surface 1014 toward a center 1019 of plate 1007 to upper or anterior surface 1012. Accordingly, the width of plate 1007 adjacent anterior surface 1012 is less than its width adjacent posterior surface 1014. Retaining element 1032 includes edges 1037 and 1041 that are substantially alignable with edges 1016 and 1018 of plate 1007, respectively. Edges 1037 and 1041 similarly taper toward center 1019 from posterior surface 1040 to anterior surface 1042, forming a continuation of the tapered profile of edges 1016, 1018. Accordingly, the lateral extent of the plating system 1000 is minimized to maintain a low-profile configuration. Retaining element 1032 can be provided with a smooth, continuous outer edge profile that minimizes stress concentrations and maximizes the material in its cross-section to resist bending and deformation loads.

When retaining element 1032 is positioned against anterior face 1012 of plate 1007, retaining element 1032 contacts a support member 1039 extending outwardly from anterior face 1012. In the illustrated embodiment, support member 1039 is an elongated ridge that extends between holes 1009, 1010 of lower nodes 1009 a, 1010 a and in the general direction of lower edge 1017. Support member 1039 can extend transversely to a central axis 1013 of plate 1007. Other orientations are also contemplated, including support member 1039 extending between nodes 1008 a and 1010 a, or extending between nodes 1008 a and 1009 a. Anterior face 1012 can further include a first planar portion 1012 a corresponding in size and shape to first portion 1032 a of retaining element 1032 so that retaining element 1032 can rest flush against first planar portion 1012 a of plate 1007. Anterior face 1012 further includes a second face portion 1012 b extending below support member 1039 that is offset from first planar portion 1012 a.

As shown in FIGS. 30 and 33-35, retaining element 1032 can include a planar posterior face 1040 and a curved anterior face 1042. Posterior face 1040 includes an abutment portion 1044 positioned relative to retaining element 1032 to abut against support member 1039, and an extension portion 1046 that extends from abutment portion 1044 along anterior face 1012 of plate 1007 between holes 1009 and 1010. In the illustrated embodiment, abutment portion 1044 extends transversely to central axis 1033. Retaining element 1032 includes a second portion 1032 b positionable along second face portion 1012 b. Second portion 1032 b can be formed by a recess in the posterior face 1040 of retaining element 1032, and can extends from an edge of retaining element 1032 to abutment portion 1044.

Retaining element 1032 resides upon and extends anteriorly from anterior face 1012 when coupled to plate 1007. Support member 1039 interacts with abutment portion 1044 to facilitate placement of retaining element 1032 in the proper position relative to plate 1007, and can prevent retaining element 1032 from rotating or moving relative to plate 1007 when retaining element 1032 is engaged thereto. In the illustrated embodiment, abutment portion 1044 and support member 1039 are elongated and extend between holes 1009, 1010 to resist pivoting of retaining element 1032 relative to plate 1007 when abutment portion 1044 is in contact with support member 1039.

FIGS. 36-38 provide a fixed retaining element 1100 that is similar to fixed retaining element 900 discussed above; however, fixed retaining element 1100 is adapted for engagement with plate 1007 having support member 1039. Retaining element 1100 has a generally triangular shape and is sized to fit on a triangular-shaped plate, such as plate 1007, although other shapes for plate 1007 and retaining element 1100 are also contemplated. Retaining element 100 includes an upper node 1102, a first lower node 1104 and a second lower node 1106. Retaining element 1000 includes a central hole 1008 sized to receive a locking fastener to secure retaining element 1000 in central opening 1029 of plate 1007. Retaining element 1000 also includes an alignment hole 1110 alignable with, for example, hole 1020 of plate 1007. Alignment hole 1110 is sized to receive an extension of an attachment instrument such as discussed above with respect to attachment instrument 800.

Each of the nodes 1102, 1104, 1106 includes a profile so that each node 1102, 1104, 1106 extends over the adjacent screw hole of plate 1007 and the head of the screw positioned therein. As shown in FIG. 37, each node 1102, 1104, 1106 includes an engagement member 1112, 1114, 1116, respectively, extending therefrom into the adjacent screw hole to engage a tool engaging portion of a respective bone screw, fixing the bone screws relative to plate 1007, as discussed above with respect to retaining element 900.

Engagement members 1112, 1114 and 1116 are received in the adjacent plate holes so that a planar posterior surface 1118 of retaining element 1100 can lie flush against the first planar portion 1012 a of plate 1007 and with a curved anterior face 1120 of retaining element 1100 facing outwardly. As discussed above with respect to retaining element 1032, posterior face 1118 includes an abutment portion 1122 configured to abut against support member 1039, and an extension portion 1124 that extends from abutment portion 1122 and second face portion 1012 b of plate 1007 between holes 1009 and 1010. Accordingly, retaining element 1100 resides upon and extends anteriorly from anterior face 1012 when coupled to plate 1007.

First planar portion 1012 a of plate 1007 can correspond in size and shape to first portion 1100 a of retaining element 1100 so that retaining element 1100 can rest flush against first planar portion 1012 a of plate 1007. Anterior face 1012 further includes second face portion 1012 b extending along support member 1039 offset from first planar portion 1012 a. Retaining element 1100 includes a second portion 1100 b extending along second face portion 1012 b. Support member 1039 interacts with abutment portion 1122 to facilitate placement of retaining element 1100 in the proper position relative to plate 1007, and can prevent retaining element 1100 from rotating or moving relative to plate 1007 when retaining element 1100 is engaged thereto.

In the illustrated embodiments for retaining elements 1032, 1100, abutment portions 1044, 1122 and support member 1039 of plate 1007 are elongated and extend between holes 1009, 1010 to resist pivoting of retaining elements 1032, 1100 relative to plate 1007. Extension portions 1044, 1124 of retaining elements 1032, 1100 include a posterior surface that lies in a plane offset from a plane in which posterior surfaces 1040, 1118 of first portions 1032 a, 1100 a lie. When one of the retaining elements 1032, 1100 is engaged to plate 1007, the posterior surfaces 1040, 1118 along first portions 1032 a, 1100 a can lie along first planar portion 1012 a. The posterior surface along the extension portions 1044, 1124 of second portions 1032 b, 1100 b can lie along second face portion 1012 b. Accordingly, retaining elements 1032, 1100 can be secured to plate 1007 with support member 1039 engaged with abutment portions 1044, 1122 in an overlapping, interdigitating configuration while minimizing the overall height of the plate retaining element construct between the anterior and posterior surfaces.

Various means are described herein for securing the retaining element on the plate, such as clips, locking fasteners, and pins. Clippable retaining elements, either pre-fitted or not pre-fitted, are advantageous since the retaining element can secured to the plate easily and quickly. The only manipulations by the surgeon required by clippable retaining elements that are not pre-fitted is to move the retaining element in a direction perpendicular to the plate in the space which corresponds to that which was necessary to form anyway for positioning the plate on the spinal column. Use of sliding elements is also contemplated, which necessitate the formation of an additional space to accommodate sliding insertion of the retaining element if not pre-loaded on the plate. The present invention also contemplates retaining elements secured by a threaded fastener and can either be preloaded on the plate or not preloaded on the plate. It should be understood that the present invention contemplates the use of any of the retaining element embodiments described herein with any of the plate embodiments described herein.

Examples of material which may be employed in fabrication of the plates and retaining elements of the present invention can be made from any bio-compatible non-resorbable material, such as titanium, stainless steel, shape memory alloys, and combinations thereof. Resorbable materials are also contemplated. In the embodiments of FIGS. 17-22, the body of the plate can be made from titanium, and the retaining elements made from a shape memory alloy that is formable from the first form allowing screw insertion to the second form for blocking the inserted screws. In another example, the retaining elements can be made from a material less resistant to bending forces than the plate body, which would allow the retaining elements to be more easily bent by the surgeon.

The plate assembly of the present invention may also be used in combination with various types of implants I (FIG. 2). Examples of such implants include interbody spacers, fusion device, and bone graft materials that are placed in disc space D. Further examples of such devices include bone dowels, push-in cages, screw-in cages, tapered cages, cages filled with bone graft and/or graft substitute material or other types of devices suitable for such fusion applications.

While the invention has been illustrated and described in detail in the drawings and foregoing description, the same is to be considered as illustrative and not restrictive in character, it being understood that only preferred embodiments have been shown and described and that all changes and modifications that come within the spirit of the invention are desired to be protected. 

1. A plating apparatus for the spine, comprising: a plate having a first hole alignable with an upper vertebra and a pair of second holes alignable with a lower vertebra and for receiving fasteners for engaging said plate to the lower vertebra, said plate having a first surface facing away from the upper and lower vertebrae when engaged thereto, said plate further including a support member on said first surface extending between said pair of second holes; a retaining element engageable to said plate with a second surface of said retaining element adjacent said first surface, said retaining element including an abutment portion on said second surface, wherein when engaged to said plate: said retaining element extends outwardly from said first surface and said support member of said plate in a direction opposite said first and second vertebrae; and said abutment portion is engageable with said support member to resist movement of said retaining element relative to said plate.
 2. The apparatus of claim 1, wherein said retaining element includes a first posterior surface portion extending in a first direction from said abutment portion and a second posterior surface portion extending from said abutment portion in a second direction opposite said first direction, said first and second posterior surface portions lying in planes offset from one another.
 3. The apparatus of claim 1, wherein: said plate includes a generally triangular shape having an upper node and a pair of lower nodes; an upper hole in said plate at said upper node to receive a screw for passage into an L5 vertebra; and a first lower hole in said plate formed through one of said lower nodes to receive a screw for passage into the Si vertebra and a second lower hole in said plate through the other of said lower nodes to receive a screw for passage into the S1 vertebra.
 4. The apparatus of claim 1, wherein said plate has lateral edges extending between said upper node and each of said lower nodes, said lateral edges having a concave profile.
 5. The apparatus of claim 1, wherein said plate has a posterior face positionable against the L5 vertebra and the S1 vertebra, said posterior face having a concave profile.
 6. The apparatus of claim 5, wherein said plate includes a protrusion extending from said posterior face adapted to contact the inferior margin of the L5 vertebra.
 7. The apparatus of claim 1, wherein said support member is elongated transversely to a central axis of said plate and said abutment portion is elongated in a direction transverse to a central axis of said retaining element.
 8. The apparatus of claim 1, wherein said retaining element includes an extension portion extending from said abutment portion, said extension portion including a third surface offset from said second surface of said retaining element.
 9. The apparatus of claim 8, wherein a portion of said first surface is planar and said support member extends outwardly from said portion of said first surface away from said upper and lower vertebrae.
 10. The apparatus of claim 1, wherein said plate has a central opening located between said first and second holes.
 11. The apparatus of claim 10, further comprising a fastener for attaching said retaining element to said central opening.
 12. The apparatus of claim 1, wherein: said plate and said retaining element each have a generally triangular shape; said support member extends in the direction between adjacent lower vertices of the triangularly-shaped plate; and said abutment portion extends in the direction between adjacent lower vertices of the triangularly-shaped retaining element.
 13. A plating apparatus for the spine, comprising: a plate having a generally triangular shape with an upper node positionable along an upper vertebra and a pair of lower nodes positionable along a lower vertebra; an upper hole in the plate at the upper node to receive a bone engaging fastener for engaging the upper vertebra; a first lower hole in the plate through one of the lower nodes to receive a bone engaging fastener for engaging the lower vertebra and a second lower hole in the plate through the other of the lower nodes to receive a bone engaging fastener for engaging the lower vertebra; and a retaining element engageable to said plate along a surface of said plate directed away from the upper and lower vertebrae and extending at least partially over each of said upper hole and said first and second lower holes, said surface of said plate including a support member and said retaining element including an abutment portion positionable against said support member, said support member and said abutment portion engage with one another to prevent said retaining element from rotating relative to said plate.
 14. The apparatus of claim 13, wherein said support member is an elongated ridge extending from said surface of said plate away from said upper and lower vertebrae.
 15. The apparatus of claim 14, wherein said support member extends between said first lower hole and said second lower hole.
 16. The apparatus of claim 15, wherein said abutment portion is formed in a surface of said retaining element oriented toward said plate.
 17. The apparatus of claim 16, wherein said abutment portion extends between said first lower hole and said second lower hole when said retaining element is engaged to said plate.
 18. The apparatus of claim 16, wherein said retaining element includes an extension portion formed by a recess in said surface of said retaining element, said recess extending from an edge of said retaining element to said abutment portion.
 19. The apparatus of claim 13, wherein said retaining element includes a locking fastener extending therethrough and engageable to a central opening in said plate to secure said retaining element to said plate.
 20. A plating apparatus comprising: a bone plate having at least one opening for receiving a bone engaging fastener and at least one edge extending along an outer perimeter thereof, said at least one edge including a profile from a lower surface to an upper surface of said bone plate that tapers toward a center of said bone plate; and a retaining element engageable adjacent an upper surface of said bone plate and configured to extend at least partially over said at least one hole to prevent said bone engaging fastener from backing out relative to said plate, said retaining element including at least one edge substantially alignable with said at least one edge of said bone plate, said at least one edge forming an extension of said at least one edge of said bone plate and including a profile from a lower surface to an upper surface of said retaining element that tapers toward a center of said retaining element.
 21. The apparatus of claim 20, wherein said bone plate and said retaining element each include three edges forming a triangular shape.
 22. A spinal fixation system, comprising: a plate having at least one first hole and at least one second hole therethrough between an upper surface of said plate and a lower surface of said plate, said first and second holes each sized to receive a bone screw to secure said plate to at least one vertebra; and a retaining element engageable to said plate and extending at least partially over each of said bone screws in said first hole and said second hole, said retaining element having at least first and second engagement members extending therefrom engageable with tool engaging recesses in corresponding ones said bone screws in each of said first and second holes below said upper surface of said plate to fix said bone screws relative to said plate.
 23. The system of claim 22, wherein said at least one first hole is positionable over an upper vertebra and said at least one second hole is positionable over a lower vertebra.
 24. The system of claim 23, further comprising a third hole extending through said plate positionable over the lower vertebra and sized to receive a bone screw therethrough.
 25. The system of claim 24, wherein the upper vertebra is the L5 vertebra and the lower vertebra is the S1 vertebra.
 26. The system of claim 24, wherein said plate has a generally triangular shape and said retaining element has a generally triangular shape, said retaining element including a third engagement member engageable with a tool engaging recess of a bone screw in said third hole.
 27. The system of claim 26, wherein each of said engagement members includes a central protrusion positionable in said tool engaging recess of each of said bone screws and a recess extending around said central protrusion sized to receive a head of each of said bone screws.
 28. The system of claim 22, wherein each of said engagement members includes a central protrusion positionable in said tool engaging recess of each of said bone screws and a recess extending around said central protrusion sized to receive a head of each of said bone screws.
 29. The system of claim 22, further comprising a locking fastener to engage said retaining element to a threaded hole in said plate.
 30. The system of claim 22, wherein said retaining element has a lower surface positioned against said upper surface of said plate.
 31. The system of claim 30, wherein said retaining element extends above said upper surface of said plate.
 32. A system for stabilizing a spinal column segment, comprising: a plate having at least first and second holes for receiving first and second bone screws to attach said plate to at least one vertebra, said plate having a receptacle; a retaining element engageable to said plate, said retaining element having a receptacle; and an attachment instrument having a distal end coupled to said retaining element and having an extension extending through said receptacle of said retaining element and positionable in said receptacle of said plate with said retaining element in a desired orientation with respect to said plate, wherein said attachment instrument is operable to advance said retaining element along said extension in said desired oriented for engagement of said retaining element to said plate.
 33. The system of claim 32, wherein said attachment instrument includes an inner member rotatably received in an outer shaft.
 34. The system of claim 33, wherein said outer shaft includes a foot extending laterally at said distal end of said attachment instrument and said extension extends distally from said foot.
 35. The system of claim 34, wherein said inner member includes driver at a distal end of said attachment instrument for engagement with a locking fastener extending through said retaining element, said locking fastener engageable with said plate to engage said retaining element thereto.
 36. The system of claim 32, wherein said first bone screw secures said plate to an upper vertebra and said second bone screw secures said plate to a lower vertebra.
 37. The system of claim 36, further comprising a third hole extending through said plate sized to receive a third bone screw to secure the plate to the lower vertebra.
 38. The system of claim 37, wherein the upper vertebra is the L5 vertebra and the lower vertebra is the S1 vertebra.
 39. The system of claim 37, wherein said plate has a generally triangular shape and said retaining element has a generally triangular shape. 